CN113417070A - Antibacterial spunlace fabric and preparation method thereof - Google Patents

Abstract

The invention discloses an antibacterial spunlace fabric and a preparation method thereof, and relates to the technical field of non-woven fabrics, wherein the antibacterial spunlace fabric comprises the following raw materials in parts by weight: 5-60 parts of strongly basic anion exchange fiber, 40-95 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber, and the preparation method of the antibacterial spunlace fabric comprises the following steps: step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino; and secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain the strongly basic anion exchange fiber, wherein the produced spunlace fabric contains a strongly basic anion exchange fiber material, and the strongly basic anion exchange fiber has good antibacterial performance, so that beauty tools such as soft towels, facial masks and masks, daily protective articles and the like which are produced by using the spunlace fabric as a raw material have good antibacterial performance.

Description

Antibacterial spunlace fabric and preparation method thereof

Technical Field

The invention relates to the technical field of non-woven fabrics, in particular to an antibacterial spunlace fabric and a preparation method thereof.

Background

Wet tissues, wipes, facial masks and the like have penetrated into our lives and are used in large quantities. However, wet tissues, wipes, face masks, and the like are currently manufactured from nonwoven fabrics made of paper or chemical fibers.

A strong-basicity anion exchange fiber material and a synthetic method thereof are disclosed in a Chinese patent with an authorization publication number of CN101879466B, belonging to the technical field of high polymer materials. The invention takes acrylic fiber as a basic skeleton, firstly aminates with a polyamino compound to introduce amido, and then reacts with glycidol trimethyl ammonium chloride to introduce quaternary ammonium group, thus obtaining a novel strong-alkaline anion exchange fiber material. The fiber material can exchange Cr (VI) and other anion pollutants within a wide pH value range (such as pH 1-11), and can further meet the requirement of actual wastewater treatment. Compared with granular adsorbing materials, the fiber material has the advantages of large specific surface area, small flow resistance, high adsorption speed, large adsorption capacity, easy elution and regeneration and the like, and can be processed into various forms such as fiber bundles, non-woven fabrics, fabrics and the like. The synthetic method has the advantages of simple process, easy control and mild reaction conditions.

The strong-alkaline anion exchange fiber material prepared by the scheme has a good antibacterial effect, and spunlace fabrics for manufacturing soft towels, wet tissues, wiping towels, facial masks and the like need to have antibacterial performance, so that the strong-alkaline anion exchange fiber material prepared by the scheme can be added during production of the spunlace fabrics to improve the antibacterial performance of the spunlace fabrics, and therefore the soft towels, the facial masks and other cosmetic tools, daily protective articles and the like which are manufactured by taking the material provided by the invention as a raw material have good antibacterial performance.

Disclosure of Invention

The invention aims to provide antibacterial spunlace fabric and a preparation method thereof, and aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight: 5-60 parts of strong-base anion exchange fiber, and 40-95 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber.

The bacteriostatic spunlace fabric comprises the following raw materials in parts by weight: 20-50 parts of strong-base anion exchange fiber, and 60-80 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber.

The bacteriostatic spunlace fabric comprises the following raw materials in parts by weight: 40 parts of strong-base anion exchange fiber, 70 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber.

The natural fiber is cotton fiber.

The conventional fiber is a polyester fiber.

The differential fibers are ultra-fine fibers.

The high-function fiber is pearl fiber.

The invention also provides a preparation method of the antibacterial spunlace fabric, which comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber and other fiber materials together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

The other fibers are one or more of natural fibers, conventional fibers, differential fibers, and high-functional fibers.

The conventional fiber is polyester fiber, the differential fiber is superfine fiber, and the high-function fiber is pearl fiber.

Compared with the prior art, the invention has the beneficial effects that:

because the strong-alkaline anion exchange fiber has good bacteriostatic effect, wet tissues, wiping tissues, facial masks and the like which are manufactured by taking the fiber as a raw material have good bacteriostatic performance.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to specific embodiments, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

5 parts of strong-base anion exchange fiber and 40 parts of cotton fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber and the cotton fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 2:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

60 parts of strong-base anion exchange fiber and 95 parts of polyester fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber and the polyester fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 3:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

20 parts of strong-base anion exchange fiber and 60 parts of superfine fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber and the superfine fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 4:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

50 parts of strong-base anion exchange fiber and 80 parts of pearl fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber and the pearl fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 5:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

40 parts of strong-base anion exchange fiber, 40 parts of cotton fiber and 30 parts of polyester fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber, the cotton fiber and the polyester fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 6:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

5 parts of strong-base anion exchange fiber, 30 parts of cotton fiber, 27 parts of polyester fiber, 20 parts of superfine fiber and 18 parts of pearl fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber, the cotton fiber, the polyester fiber, the superfine fiber and the pearl fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 7:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

60 parts of strong-base anion exchange fiber, 20 parts of superfine fiber and 20 parts of pearl fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber, the superfine fiber and the pearl fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

Example 8:

the bacteriostatic spunlace fabric comprises the following raw materials in parts by weight:

37 parts of strong-base anion exchange fiber, 30 parts of cotton fiber and 40 parts of pearl fiber.

A preparation method of the antibacterial spunlace fabric comprises the following steps:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber, the cotton fiber and the pearl fiber together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

The water-punched cloth prepared by the invention contains strong-alkaline anion exchange fiber materials, and the strong-alkaline anion exchange fibers have good antibacterial performance, so that the water-punched cloth has good antibacterial performance for beauty tools such as soft towels, facial masks, masks and the like, daily protective articles and the like which are manufactured by taking the water-punched cloth as a raw material.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The bacteriostatic spunlace fabric is characterized by comprising the following raw materials in parts by weight: 5-60 parts of strong-base anion exchange fiber, and 40-95 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber.

2. The bacteriostatic spunlace fabric according to claim 1, which is characterized by comprising the following raw materials in parts by weight: 20-50 parts of strong-base anion exchange fiber, and 60-80 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber.

3. The bacteriostatic spunlace fabric according to claim 1, which is characterized by comprising the following raw materials in parts by weight: 40 parts of strong-base anion exchange fiber, 70 parts of one or more of natural fiber, conventional fiber, differential fiber and high-functional fiber.

4. A bacteriostatic spunlace fabric according to claim 1, 2 or 3, wherein the natural fibers are cotton fibers.

5. A bacteriostatic spunlace fabric according to claim 1, 2 or 3, wherein the conventional fibers are polyester fibers.

6. The bacteriostatic spunlace fabric according to claim 1, 2 or 3, wherein the differential fiber is an ultrafine fiber.

7. The bacteriostatic spunlace fabric according to claim 1, 2 or 3, wherein the high-functional fibers are pearl fibers.

8. The preparation method of the bacteriostatic spunlace fabric according to any one of claims 1 to 7, which is characterized by comprising the following steps of:

step one, acrylic fiber is used as a basic skeleton and reacts with a poly amino compound to introduce amino;

secondly, introducing quaternary ammonium groups through the reaction of amino groups and glycidol trimethyl ammonium chloride in a solvent to obtain strongly basic anion exchange fibers;

step three, mixing the strong-base anion exchange fiber and other fiber materials together to obtain mixed fiber;

step four, mechanically carding the mixed fibers into a web in a disordered way to obtain a fiber web;

fifthly, forming the antibacterial spunlace fabric by spunlacing the fiber net;

and step six, drying the antibacterial spunlace fabric.

9. The method for preparing bacteriostatic spunlace fabric according to claim 8, wherein the other fibers are one or more of natural fibers, conventional fibers, differential fibers and high-functional fibers.

10. The method for preparing bacteriostatic spunlace fabric according to claim 9, wherein the natural fiber is cotton fiber, the conventional fiber is polyester fiber, the differential fiber is superfine fiber, and the high-functional fiber is pearl fiber.